Smooth \%MinMax: A Differentiable Relaxation for Codon Harmonization
Abstract
Codon harmonization aims to adapt the coding sequences for heterologous expression while preserving the native-like patterns of frequent and rare codons that may influence local translation dynamics and co-translational protein folding. However, widely used harmonization metrics, such as \%MinMax, are defined on discrete codon sequences and are, therefore, not readily compatible with gradient-based neural codon design. Here, we introduce Smooth \%MinMax, denoted as \% MinMax(s), a differentiable relaxation of the conventional hard \%MinMax metric, denoted as \% MinMax(h). \% MinMax(s) replaces the discrete codon-usage values with probability-weighted synonymous-codon usage values and replaces the hard \%Max/\%Min branch with a sigmoid-gated interpolation. This formulation preserves the signed interpretation of \% MinMax(h), while enabling optimization with respect to the synonymous-codon probabilities and learnable parameters. In human-to-Escherichia coli codon harmonization experiments, \% MinMax(s) closely approximates \% MinMax(h) and supports gradient-based profile matching in synonymous-codon probability space. These results suggest \% MinMax(s) as a practical bridge between profile-based codon harmonization and neural synonymous-sequence design.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.